Water is the one of the major commodities used by the pharmaceutical industry. It is widely used as a raw material, ingredient, and solvent in the processing, formulation, and manufacture of pharmaceutical products, active pharmaceutical ingredients (APIs) and intermediates, compendial articles, and analytical reagents.[1]
Pharmaceutical water
The water that is used directly for the drug manufacturing
process and indirectly for the system and equipments cleaning is known as
pharmaceutical water.
Classification of
Pharmaceuticals Water
|
Name |
Definition |
|
Purified Water |
A clear, colorless, order less and
tasteless liquid that complies all relevant regulations. |
|
Sterile Purified Water |
Purified water that is sterilized and
suitably packed. |
|
Water for Injection |
A clear, colorless, order less,
tasteless and pyrogenic liquid that complies all relevant regulations. |
|
Sterile Water for
Injection |
Water for injection that is sterilized
and suitably packed. |
|
Bacteriostatic Water for
Injection |
Bacteriostatic water for injection is
steriled water for injection that contains one or more anti-microbial agents.
It is intended to use to use as a
diluent in the preparation of parenteral products. |
|
Sterile Water for
Irrigation |
Water for injection that is suitably
packed in a single dose container and rendered sterile and is intended to be
delivered rapidly. |
|
Sterile Water for
Inhalation |
Water for injection that is packed and
rendered sterile and is intended for use in inhalators and in the preparation
of inhalation solution. |
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Use of Pharmaceutical
Water
|
Name |
Uses |
|
Purified Water |
1. Liquid preparation 2. Equipment cleaning 3. Bulk chemical manufacturing |
|
Sterile Purified Water |
Ophthalmic Preparation |
|
Water for Injection |
1. Parenteral preparation 2. Equipment cleaning 3. Bulk chemical manufacturing |
|
Sterile Water for
Injection |
1. Parenteral preparation 2. Equipment cleaning 3. Bulk chemical manufacturing |
|
Bacteriostatic Water for
Injection |
Some parenteral products preparation
or dilution. |
|
Sterile Water for
Irrigation |
To wash after operation. |
|
Sterile Water for
Inhalation |
Inhalation preparation. |
Pharmaceutical water quality standards
PHYSICAL STANDARD [2]
|
Sr No. |
Characteristics |
Acceptable* |
Cause for
Rejection* |
|
1 |
Turbidity (units on J.T.U.
scale) |
2.5 |
10 |
|
2 |
Colour (units on
platinum-cobalt scale) |
5.0 |
25 |
|
3 |
Taste and odour |
Unobjectionable |
Unobjectionable |
CHEMICAL STANDARD [2]
|
Sr No. |
Characteristics |
Acceptable* |
Cause for
Rejection* |
|
1 |
pH |
7.0-8.5 |
6.5-9.2 |
|
2 |
Total dissolved solids
(mg/l) |
500 |
1500 |
|
3 |
Total hardness (as CaCo3)
(mg/l) |
200 |
600 |
|
4 |
Chlorides (as Cl) (mg/l) |
200 |
1000 |
|
5 |
Sulphates (as So4) (mg/l) |
200 |
400 |
|
6 |
Fluorides (as F) (mg/l) |
1.0 |
1.5 |
|
7 |
Nitrates (as No3) (mg/l) |
45 |
45 |
|
8 |
Calcium (as Ca) (mg/l) |
75 |
200 |
|
9 |
Magnesium (as Mg) (mg/l) |
>30 (If there are 250 mg/l of
sulphates, Mg content can be increased to a maximum of 125 mg/l with the
reduction of sulphates at the rate of 1 unit per every 2.5 units of
sulphates) |
150 |
|
10 |
Iron (as Fe) (mg/l) |
0.1 |
1.0 |
|
11 |
Manganese (as Mn) (mg/l) |
0.05 |
0.5 |
|
12 |
Copper (as Cu) (mg/l) |
0.05 |
1.5 |
|
13 |
Zinc (as Zn) (mg/l) |
5.0 |
15.0 |
|
14 |
Phenolic compounds (as
phenol) (m |
0.001 |
0.002 |
|
15 |
Anionic detergents (as
MBAS) (mg/ |
0.2 |
1.0 |
|
16 |
Mineral oil (mg/l) |
0.01 |
0.3 |
|
17 |
Arsenic (as As) (mg/l) |
0.05 |
0.05 |
|
18 |
Cadmium (as Cd) (mg/l) |
0.01 |
0.01 |
|
19 |
Chromium (as hexavalent
Cr) (mg/l) |
0.05 |
0.05 |
|
20 |
Cynides (as CN) (mg/l) |
0.05 |
0.05 |
|
21 |
Lead (as Pb) (mg/l) |
0.1 |
0.1 |
|
22 |
Selenium (as Se) (mg/l) |
0.01 |
0.01 |
|
23 |
Mercury (total as Hg)
(mg/l) |
0.001 |
0.001 |
|
24 |
Polynuclear aromatic hydrocarbons
(PAH) (µg/l) |
0.2 |
0.2 |
|
25 |
Gross alpha activity
(pCi/l) |
3 |
3 |
|
26 |
Gross beta activity
(pCi/l) |
30 |
30 |
|
BACTERIOLOGICAL
STANDARDS |
|
1) Water entering
the distribution system in piped supply chlorinated or otherwise disinfected
shall satisfy the following criteria : Coliform count in any sample of 100 ml
should be zero. A sample of the water entering the distribution system that
does not conform to this standard calls for an immediate investigation into
both the efficacy of the purification process and the method of sampling |
|
2) Water in the distribution system shall
satisfy these three criteria 1. E.Coli
count in 100 ml of any sample should be zero. 2. Coliform organisms not more than 10 per 100
ml shall be present in any sample. 3.
Coliform organisms should not be detectable in 100 ml of any two
consecutive samples or more than 50 percent of the samples collected for the
year |
|
3) In individual or small community supplies
E.Coli count should be zero in any sample of 100 ml and coliform organisms
should not be more than 3 per 100 ml. If coliforms exceed 3 per 100 ml, the supply should be disinfected. |
|
VIROLOGICAL
STANDARDS |
|
0.5 mg/l of free
residual chlorine for one hour is sufficient to inactivate virus, even in
water that was originally polluted. This free chlorine residual is to be
insisted in all disinfected supplies in areas suspected of endemicity of
infectious hepatities to inactivate virus and also bacteria. 0.2 mg/l of free
residual chlorine for half an hour should be insisted for other areas. |
Water purification techniques [2]
|
Techniques |
Benefits |
Limitations |
|
Distillation |
1. Removes a broad range of contaminants and therefore
useful as a first purification step. 2.
Reusable. |
1. Contaminants are carried to some extent into the
condensate. 2.Requires careful maintenance to ensure purity. 3.Consumes large amounts of tap water (for cooling)
and electrical energy (for heating).
4. Not environment-friendly. |
|
Ion exchange |
1. Removes dissolved inorganic (ions) effectively,
allowing resistivity levels above 18.0 MΩ•cm at 25 °C to be reached
(corresponding roughly to less than 1ppb total ionic contamination in water). 2. Regenerable (by acid and bases in “service
deionization” or by electrode ionization). 3. Relatively inexpensive initial capital investment. |
1. Limited capacity: once all ion binding sites are
occupied, ions are no longer retained (except when operating in an electode ionization
process). 2. Does not effectively remove organics, particles, pyrogens
or bacteria. 3. Chemically
regenerated DI beds can generate organics and particles. 4. Single use, “virgin” resins
require good pretreated water quality to be economically efficient. |
|
Activated carbon |
1. Removes dissolved organics and chlorine
effectively. 2. Long life due to high binding capacity. |
1. Does not efficiently remove ions and
particulates. 2. Limited capacity due to a high, but limited, number
of binding sites. 3. Can generate carbon fines. |
|
Ultrafiltration |
1.Effectively removes most particles, pyrogens,
enzymes, microorganisms and colloids above their rated size, retaining them
above the ultrafilter surface. 2.Efficient operation throughout their lifetime,
unless they are damaged. 3. Their lifetime can be extended by a regular water
flush at high speed. |
1. Will not remove dissolved inorganics or organic
substances. 2. May clog
when challenged by an excessive level of high-molecular-weight contaminants. |
|
Reverse osmosis |
1. Effectively removes all types of contaminants to
some extent (particles, pyrogens, microorganisms, colloids and dissolved inorganics),
and is therefore useful as a first purification step. 2. Requires minimal maintenance. 3.Operation parameters (pressure, temperature, flow rate,
ionic rejection) are easy to monitor. |
1.LImited flow rates per surface unit require either large
membrane surfaces or an intermediate storage device to satisfy user demand. 2. Requires good pretreatment to avoid rapid membrane
damage by water contaminants |
|
Elix Ion Exchange |
1.Removes dissolved inorganics effectively, allowing
resisti it above 5 Ω•cm at 25° to be reached 2. Environment-friendly No chemical regeneration No
chemical disposal No resin disposal 3. Inexpensive to operate. 4. Safe: No heating element. |
1. Removes only a limited number of charged organics. 2. Requires feed by good quality water (for instance,
reverse osmosis-treated water) for economically efficient operation. |
|
Ultraviolet (Uv) Radiation |
1. Effective sanitizing treatment. 2. Oxidation of organic compounds (185 nm and 254 nm)
to reach water TOC levels below 5 ppb. |
1. Photooxidation of organics is a polishing step,
able to decrease the TOC level only by a limited value. 2.The CO2 produced during photooxidation decreases the
water’s resistivity. 3. UV light will not affect ions, particles or
colloids. |
- QUALITY OF WATER FOR
PHARMACEUTICAL USE: AN OVERVIEW by Yaswanth Allamneni, Navya Allamneni, P
Dayananda Chary, G Vijay Kumar, Arun Kumar Kalekar, Pavan Kumar Potturi.
- WATER QUALITY FOR PHARMACEUTICAL
USE: A REVIEW, Amit V. Patel, Dipen A. Trambadiya, Lalji Baldania Vol - 4,
Issue - 3, Apr-Jul 2013
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